减氮对华北地区麦玉轮作农田土壤N2O排放调控机理

【目的】探究减氮对华北地区麦玉轮作农田土壤N2O排放调控机制。【方法】冬小麦季和夏玉米季均以不施氮为对照(CK),设置2个施氮量,分别为常规施氮量(纯氮300 kg/hm2,N2)、减氮20%(纯氮240 kg/hm2,N1),研究施氮量对麦玉轮作农田土壤性质及N2O排放通量影响,基于逐步回归分析,研究减氮对麦玉轮作农田土壤N2O排放调控机制。【结果】(1)减氮有效降低了N2O排放通量,且夏玉米季N2O排放通量远高于冬小麦季,夏玉米季由施肥引起的N2O排放量较高。(2)冬小麦季N2O排放通量与环境因子逐步回归公式为:N2O排放通量=181.952+1.450×硝态氮+8.401×铵态氮-0.514×电导率;硝态氮、铵态氮会对冬小麦季N2O排放通量产生显著的正向影响,而电导率会对冬小麦季N2O排放通量产生显著的负向影响。(3)夏玉米季N2O排放通量与环境因子逐步回归公式为:N2O排放通量=-354.606+4.592×硝态氮+157.848×铵态氮;硝态氮、铵态氮会对夏玉米季N2O排放通量产生显著的正向影响。【结论】综上可知,适量减氮显著降低夏玉米季N2O累积排放量和增温潜势,应加强夏玉米季农田水肥管理。

Designing ultrastable P2/O3-type layered oxides for sodium ion batteries by regulating Na distribution and oxygen redox chemistry

P2/O3-type Ni/Mn-based layered oxides are promising cathode materials for sodium-ion batteries(SIBs)owing to their high energy density.However,exploring effective ways to enhance the synergy between the P2 and 03 phases remains a necessity.Herein,we design a P2/O3-type Na_(0.76)Ni_(0.31)Zn_(0.07)Mn_(0.50)Ti_(0.12)0_(2)(NNZMT)with high chemical/electrochemical stability by enhancing the coupling between the two phases.For the first time,a unique Na*extraction is observed from a Na-rich O3 phase by a Na-poor P2 phase and systematically investigated.This process is facilitated by Zn^(2+)/Ti^(4+)dual doping and calcination condition regulation,allowing a higher Na*content in the P2 phase with larger Na^(+)transport channels and enhancing Na transport kinetics.Because of reduced Na^(+)in the O3 phase,which increases the difficulty of H^(+)/Na^(+) exchange,the hydrostability of the O3 phase in NNZMT is considerably improved.Furthermore,Zn^(2+)/Ti^(4+)presence in NNZMT synergistically regulates oxygen redox chemistry,which effectively suppresses O_(2)/CO_(2) gas release and electrolyte decomposition,and completely inhibits phase transitions above 4.0 V.As a result,NNZMT achieves a high discharge capacity of 144.8 mA h g^(-1) with a median voltage of 3.42 V at 20 mA g^(-1) and exhibits excellent cycling performance with a capacity retention of 77.3% for 1000 cycles at 2000 mA g^(-1).This study provides an effective strategy and new insights into the design of high-performance layered-oxide cathode materials with enhanced structure/interface stability forSIBs.

Weakly Polarized Organic Cation-Modified Hydrated Vanadium Oxides for High-Energy Efficiency Aqueous Zinc-Ion Batteries

Vanadium oxides,par-ticularly hydrated forms like V_(2)O_(5)·nH_(2)O(VOH),stand out as promising cathode candidates for aqueous zinc ion batteries due to their adjustable layered structure,unique electronic characteristics,and high theoretical capacities.However,challenges such as vanadium dissolution,sluggish Zn^(2+)diffusion kinetics,and low operating voltage still hinder their direct application.In this study,we present a novel vanadium oxide([C_(6)H_(6)N(CH_(3))_(3)]_(1.08)V_(8)O_(20)·0.06H_(2)O,TMPA-VOH),developed by pre-inserting trimethylphenylammonium(TMPA+)cations into VOH.The incorporation of weakly polarized organic cations capitalizes on both ionic pre-intercalation and molecular pre-intercalation effects,resulting in a phase and morphology transition,an expansion of the interlayer distance,extrusion of weakly bonded interlayer water,and a substantial increase in V^(4+)content.These modifications synergistically reduce the electrostatic interactions between Zn^(2+)and the V-O lattice,enhancing structural stability and reaction kinetics during cycling.As a result,TMPA-VOH achieves an elevated open circuit voltage and operation voltage,exhibits a large specific capacity(451 mAh g^(-1)at 0.1 A g^(-1))coupled with high energy efficiency(89%),the significantly-reduced battery polarization,and outstanding rate capability and cycling stability.The concept introduced in this study holds great promise for the development of high-performance oxide-based energy storage materials.

不同盐渍化土壤n2o排放对生物炭添加和土壤水分的响应

为探讨不同盐渍化程度土壤N_(2)O排放对生物炭添加和土壤水分的响应,开展为期30 d的室内培养试验,设置5个土壤盐渍化水平(S0、S1、S2、S3、S4:盐分添加量分别为土壤质量的0%、0.25%、0.5%、0.75%、1%)、2个生物炭添加方式(B0:不添加;B1:添加量为土壤质量的5%)和2个水分条件(W0:60%田间持水量;W1:100%田间持水量)。结果表明:土壤盐分对N_(2)O累积排放量具有显著影响,盐分含量越高则降幅越大,与S0处理相比,S1、S2、S3、S4处理N_(2)O累积排放量分别降低43.9%、66.5%、91.9%、93.2%。土壤水分对N_(2)O累积排放量具有极显著影响,水分含量越高则累积排放量越大,与W0处理相比,W1条件下各盐分处理N_(2)O累积排放量分别增加3.0%、84.8%、187.4%、729.4%、306.7%。生物炭添加对N_(2)O累积排放量存在一定影响,与B0处理相比,低水含量下,B1处理累积排放量增幅为3.4%~20.6%,高水含量增幅为46.5%~535.6%。结果显示,土壤盐渍化程度越高则N_(2)O累积排放量越低,土壤水分在N_(2)O排放中占据主导作用,土壤含水量越高则N_(2)O累积排放量增幅越大,生物炭单一因素对N_(2)O排放无显著影响,但其与盐分的交互作用对N_(2)O排放有显著影响,生物炭的添加在一定程度上会抑制N_(2)O排放。

Fabrication of Gd_(2)O_(3)-doped CeO_(2)thin films through DC reactive sputtering and their application in solid oxide fuel cells

Physical vapor deposition(PVD)can be used to produce high-quality Gd_(2)O_(3)-doped CeO2(GDC)films.Among various PVD methods,reactive sputtering provides unique benefits,such as high deposition rates and easy upscaling for industrial applications.GDC thin films were successfully fabricated through reactive sputtering using a Gd_(0.2)Ce_(0.8)(at%)metallic target,and their application in solid oxide fuel cells,such as buffer layers between yttria-stabilized zirconia(YSZ)/La0.6Sr0.4Co0.2Fe0.8O_(3−δ)and as sublayers in the steel/coating system,was evaluated.First,the direct current(DC)reactive-sputtering behavior of the GdCe metallic target was determined.Then,the GDC films were deposited on NiO-YSZ/YSZ half-cells to investigate the influence of oxygen flow rate on the quality of annealed GDC films.The results demonstrated that reactive sputtering can be used to prepare thin and dense GDC buffer layers without high-temperature sintering.Furthermore,the cells with a sputtered GDC buffer layer showed better electrochemical performance than those with a screen-printed GDC buffer layer.In addition,the insertion of a GDC sublayer between the SUS441 interconnects and the Mn-Co spinel coatings contributed to the reduction of the oxidation rate for SUS441 at operating temperatures,according to the area-specific resistance tests.

Comparative structural and electrochemical properties of mixed P2/O′3-layered sodium nickel manganese oxide prepared by sol-gel and electrospinning methods:Effect of Na-excess content

The effect of Na-excess content in the precursor on the structural and electrochemical performances of sodium nickel manganese oxide(NNMO)prepared by sol-gel and electrospinning methods is investigated in this paper.X-ray diffraction results of the prepared NNMO without adding Na-excess content indicate sodium loss,while the mixed phase of P2/O′3-type layered NNMO presented after adding Na-excess content.Compared with the sol-gel method,the secondary phase of NiO is more suppressed by using the electrospinning method,which is further confirmed by field emission scanning electron microscope images.N_(2) adsorption-desorption isotherms show no remarkably difference in specific surface areas between different preparation methods and Na-excess contents.The analysis of X-ray absorption near edge structure indicates that the oxidation states of Ni and Mn are+2 and+4,respectively.For the electrochemical properties,superior electrochemical performance is observed in the NNMO electrode with a low Na-excess content of 5wt%.The highest specific capacitance is 36.07 F·g^(-1)at0.1 A·g^(-1)in the NNMO electrode prepared by using the sol-gel method.By contrast,the NNMO electrode prepared using the electrospinning method with decreased Na-excess content shows excellent cycling stability of 100%after charge-discharge measurements for 300 cycles.Therefore,controlling the Na excess in the precursor together with the preparation method is important for improving the electrochemical performance of Na-based electrode materials in supercapacitors.

灌溉和种植方式对双季稻田NH3挥发和N2O排放的影响

【目的】探究种植和灌溉方式对双季稻全生育期水分利用效率以及氮素气态损失的影响。【方法】以双季稻田为研究对象,在江西省灌溉试验中心站研究基地开展大田试验,设置手工栽插(HT)、机械插秧(MT)、抛秧(ST)、直播(DS)四种种植方式,淹水灌溉(FI)和间歇灌溉(II)两种灌溉方式,分析不同种植和灌溉方式对双季稻全生育期水分利用效率以及秧田期、本田期NH3挥发及N2O排放的影响,提出NH3挥发和N2O排放的主要时期。【结果】结果表明:(1)与传统淹水灌溉相比,间歇灌溉下水稻产量略有增加,不同种植方式间产量差异显著,HT最高,DS最低。(2)同一种植方式下,间歇灌溉下N2O排放量较淹水灌溉增加约7.9%~16.4%,同一灌溉方式下,早稻N2O损失量大小为DS>MT>HT>ST,晚稻为DS>HT>MT>ST,早、晚稻N2O排放主要发生在分蘖期、拔节孕穗期、成熟期,3个生育阶段N2O损失量占比超过70%,而育秧期MT、ST占比不到1.5%,HT为6.4%。(3)同一种植方式下,早、晚稻NH3挥发损失量淹水灌溉比间歇灌溉增加了3.0%~30.8%,同一灌溉方式下,DS相比移栽稻显著增加NH3挥发(P<0.05),HT、MT、ST之间无显著差异,NH3挥发峰值均在施肥后3 d内出现,且主要发生在苗期、分蘖期、拔节孕穗期3个时期,其NH3挥发损失量之和占整个生育期NH3挥发损失量80%以上,育秧期MT、ST占比不到2%,HT达4.2%。【结论】在不同种植方式下,间歇灌溉方式会提高双季稻产量和N2O排放,但会降低NH3挥发,从早、晚稻生育阶段来看,N2O损失主要发生在生育前期和后期,NH3挥发损失主要发生在生育前中期,且育秧期NH3挥发和N2O排放占比较低,DS在显著降低产量的同时带来了更高的N2O排放和NH3挥发。

Activation of Transition Metal(Fe,Co and Ni)-Oxide Nanoclusters by Nitrogen Defects in Carbon Nanotube for Selective CO_(2) Reduction Reaction

The electrochemical carbon dioxide reduction reaction(CO_(2)RR),which can produce value-added chemical feedstocks,is a proton-coupled-electron process with sluggish kinetics.Thus,highly efficient,cheap catalysts are urgently required.Transition metal oxides such as CoO_(x),FeO_(x),and NiO_(x)are low-cost,low toxicity,and abundant materials for a wide range of electrochemical reactions,but are almost inert for CO_(2)RR.Here,we report for the first time that nitrogen doped carbon nanotubes(N-CNT)have a surprising activation effect on the activity and selectivity of transition metal-oxide(MO_(x)where M=Fe,Ni,and Co)nanoclusters for CO_(2)RR.MO_(x)supported on N-CNT,MO_(x)/N-CNT,achieves a CO yield of 2.6–2.8 mmol cm−2 min−1 at an overpotential of−0.55 V,which is two orders of magnitude higher than MO_(x)supported on acid treated CNTs(MO_(x)/O-CNT)and four times higher than pristine N-CNT.The faraday efficiency for electrochemical CO_(2)-to-CO conversion is as high as 90.3%at overpotential of 0.44 V.Both in-situ XAS measurements and DFT calculations disclose that MO_(x)nanoclusters can be hydrated in CO_(2)saturated KHCO_(3),and the N defects of N-CNT effectively stabilize these metal hydroxyl species under carbon dioxide reduction reaction conditions,which can split the water molecules and provide local protons to inhibit the poisoning of active sites under carbon dioxide reduction reaction conditions.

田间老化生物质炭减缓稻麦轮作系统土壤N2O排放能力降低的机理

生物质炭作为一种重要的土壤调节剂,在固碳减排尤其氧化亚氮(N_(2)O)减排方面的作用日益突出。为明确生物质炭对田间N_(2)O排放的持续效应及其作用机理,通过田间定位试验,分析稻麦轮作体系新鲜和田间不同时间老化生物质炭对N_(2)O排放的影响。试验共设置5个处理,分别为CK(不施氮肥和生物质炭)、N(施氮肥)、NB0y(氮肥+新鲜生物质炭)、NB2y(氮肥+2年老化生物质炭)和NB5y(氮肥+5年老化生物质炭),动态监测稻麦轮作周期N_(2)O排放,测定水稻和小麦收获后土壤理化性质和氮循环功能基因丰度。结果表明,生物质炭显著降低土壤N_(2)O累积排放量32.4%~54.0%,且表现为NB0y>NB2y>NB5y。与N处理相比,NB0y、NB2y和NB5y处理显著提高土壤pH 0.6~1.2个单位、土壤有机碳(SOC)含量21.4%~58.6%、硝态氮( NO_(3)^(-)-N)含量1.7%~31.3%,对土壤pH改善能力随着生物质炭老化而下降。生物质炭处理显著提高nosZ基因丰度54.9%~249.4%,土壤(nirS+nirK)/nosZ比值随着生物质炭老化而增加。相关性分析表明,土壤N_(2)O累积排放量与pH呈显著负相关,与 NO_(3)^(-)-N含量和amoA-AOB(氨氧化细菌)丰度呈显著正相关。因此,新鲜和田间不同时间老化生物质炭均能显著改善土壤理化特性,降低土壤N_(2)O排放且新鲜生物质炭的作用效果优于老化生物质炭。土壤NO_(3)^(-)-N含量及(nirS+nirK)/nosZ比值的增加,是导致老化生物质炭减排N_(2)O能力降低的主要原因。

七氟醚-N2O麻醉对青年小鼠空间学习和记忆功能及pCREB和Egr1表达的影响

目的研究七氟醚-N2O麻醉后青年小鼠的空间学习和记忆能力以及海马磷酸化环腺苷酸应答元件结合蛋白(phosphorylated cyclic AMP response element-binding protein,pCREB)和早期生长反应因子1(early growth response factor 1,Egr1)的表达,并与老年小鼠进行比较。方法12只3月龄和12只18月龄小鼠随机分为对照组和实验组,每组各6只。48 h后进行为期6天的获得训练。获得训练结束后24 h进行空间探索实验,实验结束后15 min收集两组小鼠的海马组织,通过Western blot和实时定量PCR方法评估pCREB和Egr1的表达水平。结果未见麻醉损害青年小鼠的空间学习和记忆功能以及海马中pCREB和Egr1的表达水平,麻醉组与对照组比较差异均无统计学意义;而老年小鼠Sev+N2O组在麻醉后第4、5、6天逃逸潜伏期显著长于对照组(P<0.05),两组小鼠游泳速度差异无统计学意义;在空间探索实验中,Sev+N2O组目标象限路程百分比和时间百分比显著低于对照组(P<0.01);海马中pCREB和Egr1的表达水平均较对照组显著下降(P<0.05)。结论七氟醚-N2O麻醉对青年小鼠的空间学习记忆能力没有损害,也不影响海马中pCREB和Egr1的表达,但会对老年小鼠造成损害。

Z型异质结Cu_(2)O/Bi_(2)MoO_(6)的构建及光催化降解性能

通过水热法制备出一系列Z型异质结Cu_(2)O/Bi_(2)MoO_(6)新型光催化剂。采用扫描电子显微镜、粉末X射线衍射、红外光谱、紫外可见吸收光谱等表征手段研究了催化剂的形貌、结构性质和光电化学性质,并以四环素(TC)为降解目标污染物,进一步探究了其催化效率。实验结果表明,Cu_(2)O的加入提高了复合催化剂的光催化性能,其中20%Cu_(2)O/Bi_(2)MoO_(6)复合催化剂(Cu_(2)O和Bi_(2)MoO_(6)的质量比为20%)降解效果最好,100 min内可降解95%的TC。Cu_(2)O与Bi_(2)MoO_(6)之间的协同作用使其可以吸收更多的可见光,所构建的Z型异质结改变了电子转移途径,提高了电子与空穴的分离效率,光催化活性显著提高。通过自由基捕获实验和能带结构,分析了Z型异质结Cu_(2)O/Bi_(2)MoO_(6)复合催化剂光催化降解TC可能的机理。

钯催化合成N-芳基-γ-胺基-γ-丁内酰胺类化合物

γ-丁内酰胺是很多具有生物活性、药物活性化合物的核心结构单元。已报道的由过渡金属催化,直接合成N-芳基-γ-胺基-γ-丁内酰胺类化合物的反应,存在必须使用过氧化物、操作不便的局限性。以10%(物质的量分数,下同)Pd/C为催化剂,将芳香胺和N-甲基吡咯烷酮在空气气氛下的二甲苯中于100℃反应24 h得到N-芳基-γ-胺基-γ-丁内酰胺类化合物(3a~3g),产率高达91%。经过核磁氢谱、碳谱和高分辨质谱分析,产物的结构得到确证。

不同盐度滨海盐渍土壤N_(2)O排放特征

[目的]滨海盐渍土壤作为耕地的后备资源,具有强大的生产潜力,科学改良应用盐渍土壤的同时综合考量温室气体的排放,有利于实现经济-环境的双赢。探究不同盐度滨海盐渍土N_(2)O排放规律特征,可为后续盐渍土壤盐度管控和温室效应的应对提供科学依据。[方法]采集自然形成的不同盐度梯度的滨海盐渍土壤进行室内培养试验,土壤盐度分别为0.96、2.57、4.04和15.23 mS·cm^(-1),并依次命名为Y1、Y2、Y3、Y4,采用气相色谱动态监测土壤N_(2)O的排放特征。[结果]不同盐分浓度影响下盐渍土壤N_(2)O累积排放量存在显著差异,当土壤盐度为0.96~4.04 mS·cm^(-1)时,随着盐度上升,土壤N_(2)O排放量下降;当盐度达到15.23 mS·cm^(-1)时,N_(2)O再次被刺激产生,排放量(2598.94μg·kg^(-1))仅次于轻度盐渍土(5384.17μg·kg^(-1))。盐度的增加给土壤微生物生存带来压力,氨氧化细菌AOB相较于古菌AOA更易受到盐分的影响,在轻、重度盐渍化土壤(Y1、Y2、Y3)中AOA仍能保持较高丰度;而在高盐分土壤(Y4)中,AOA和AOB的相对丰度受到抑制,阻碍了硝化作用的进行。盐度梯度影响下N_(2)O累积排放量还与反硝化潜势(PDR)呈显著正相关。当盐度持续增加,土壤类型划分为盐土(Y4)时,nosZ基因丰度显著降低,N_(2)O还原作用减弱,使得Y4盐渍土中的氮素最终以N_(2)O的形式排放。[结论]盐度梯度影响滨海盐渍土壤硝化和反硝化进程,二者共同促进了土壤氮素的转化,造成N_(2)O排放的差异。当EC_(2.5∶1)为0.96~4.04 mS·cm^(-1)时,盐度的提高限制硝化、反硝化作用的速率,表现出N_(2)O的减排;当盐分分类达到盐土标准时,由硝化作用产生的N_(2)O减少,由反硝化作用(异养反硝化和硝化细菌反硝化)产生的N_(2)O成为盐土土壤的主要温室气体排放来源。

肥水管理方式对蔬菜田N2O释放影响的模拟研究

通过田间静态箱监测和DNDC模型模拟的方法,对比研究了崇明岛东滩蔬菜田在常规肥水管理和精确滴灌施肥方式下N2O的排放情况,从排放特征、全年通量、单位氮肥N2O损失率以及单位作物产量排放量等方面分析了不同肥水管理方式对旱田土壤N2O排放的影响。结果表明,基于土壤和作物养分平衡管理的精确滴灌施肥技术,由于减少了氮肥施用量并改进了肥水分配方式,提高了肥料的利用效率,在保持农作物产量的基础上减少了N2O的排放。与常规肥水管理方式相比,滴灌施肥区2006年和2007年的N2O排放通量分别减少6.2和6.8kgN·hm-2·a-1,单位氮肥N2O损失率明显降低,2006年和2007年单位产量排放量分别削减53.2%和58.9%。

DO浓度对生活污水硝化过程中N2O产生量的影响

为确定污水脱氮过程中最优的DO浓度和曝气方式,以提高污水处理效率,降低N2O产生量,采用实际生活污水应用小试SBR反应器,重点考察了不同DO浓度条件下,硝化效率和硝化过程中N2O的产生量.结果表明,当DO浓度恒定为0.4mg.L-1时,虽然硝化过程所消耗的能量最低,但其氨氮氧化的速率较低.提高DO浓度,氨氮氧化速率可随之升高.低氨氮生活污水硝化过程中仍有N2O产生.DO浓度为0.4 mg.L-1和0.9 mg.L-1时,污水N2O产生量(以N计)分别为1.5 mg.L-1和1.6mg.L-1;而DO浓度为1.5 mg.L-1和2.0 mg.L-1时,N2O产生量则分别降低至0.5 mg.L-1和0.4 mg.L-1.当DO浓度高于1.5mg.L-1后,继续提高DO浓度,氨氮氧化速率升高的速率变缓,同时N2O产生量大幅降低.因此,从提高污水脱氮效率节能降耗和控制N2O产生量2个角度考虑,生活污水脱氮过程中控制DO浓度在1.5 mg.L-1较为适宜.

(H_(2)O)_(n)^(+)(n=2~5)团簇离子在308 nm处的光解动力学

本文利用一套高分辨圆柱形低温离子阱速度成像谱仪装置研究了小团簇离子(H_(2)O)_(n)^(+)(n=2-5)在308 nm处的光解动力学.通过记录光解产物碎片质谱和速度影像,发现二聚体水团簇(H_(2)O)_(2)^(+)解离生成H_(3)O^(+)和H_(2)O^(+)光碎片,表明其同时存在质子转移(H_(3)O^(+)-OH)和半束缚(H_(2)O-OH_(2))+两种构型,水团簇离子(H_(2)O)_(n)^(+)(n=3~5)普遍通过同时丢失OH和H_(2)O部分解离得到H+(H_(2)O)_(n-2,…,1)光碎片,并且(H_(2)O)_(5)^(+)团簇离子有一个仅通过丢失OH的额外通道得到H+(H_(2)O)4.前者表明(H_(2)O)_(n)^(+)(n=3~5)的构型是(H_(2)O)_(n-2)H_(3)O^(+)OH,后者表明在(H_(2)O)_(5)^(+)团簇离子中核H_(3)O^(+)和OH被H_(2)O分开.基于实验影像得到的光碎片各向异性参数为负值并且值较小,表明(H_(2)O)_(n)^(+)(n=2~5)团簇离子在光子吸收后经历垂直电子跃迁,随后缓慢解离,并导致光碎片的高内部激发.

氮肥水平对不同土壤N2O排放的影响

鉴于N2O排放量占施用氮肥量的比例即N2O排放系数还有很大不确定性,室外盆栽试验于2002-2003年选取3个供试土壤,各土壤设置对照和低、中、高氮肥水平,全年施尿素量（以N计）分别为334、670和1 004 kg/hm^2.结果表明,水稻生长季,各个土壤的N2O累积排放量与其对照相比的增加量在低、中、高氮肥水平间无明显差异;而小麦生长季,随氮肥施用量增加,各个土壤的N2O累积排放量与其对照相比的增加量在3种氮肥水平之间的差异显著.整个稻麦轮作系统,随氮肥用量的增加明显促进麦田N2O的排放.无论水稻或小麦生长季,对照3个土壤的N2O累积排放量并无显著差异,F土壤（江苏溧水）、G土壤（江苏涟水）和H土壤（江苏农科院）的N2O累积排放量,在水稻生长季分别为168、127和146 mg/m^2;小麦生长季,分别为134、124和168 mg/m^2.在施氮肥后,3个土壤的N2O排放量出现差异,如在中氮水平下,小麦生长季,F土壤、G土壤和H土壤N2O累积排放量分别为976、744和626 mg/m^2.稻麦轮作生长季内,在低氮与中氮2个水平下,不同土壤间N2O排放系数存在显著差异.以1个稻麦轮作周期为时间尺度,F土壤、G土壤和H土壤总的N2O排放系数分别为1.1%±0.23%、0.75%±0.17%和1.01%±0.11%,表明不同土壤对N2O排放系数的影响不同.

京郊典型设施蔬菜地土壤 N2O 排放特征

利用静态暗箱-气相色谱法对北京郊区设施蔬菜地典型种植模式(番茄-白菜-生菜)下土壤N2O排放特征进行了周年(2012年2月22日—2013年2月23日)观测,探讨了不同处理下(即不施氮肥处理(CK)、农民习惯施肥处理(FP)、减氮优化施肥处理(OPT)和减氮优化施肥+硝化抑制剂处理(OPT+DCD))N2O排放特征及土壤温度、土壤湿度、土壤无机氮含量对土壤N2O排放的影响。结果表明:每次施肥+灌溉之后设施蔬菜地会出现明显的N2O排放高峰,持续时间一般为3—5 d。不同处理N2O排放通量变化范围在-0.21—14.26 mg N2O m-2h-1,平均排放通量0.03—0.36 mg N2O m-2h-1。整个蔬菜生长季各处理N2O排放与土壤孔隙含水率(WFPS)均表现出极显著的正相关关系(P<0.01);不施氮处理5 cm深度土壤温度与N2O排放通量呈现显著的正相关关系(P<0.05);各处理N2O排放与土壤表层硝态氮含量具有较一致变化趋势。不同处理下N2O年度排放总量差异显著,依次顺序为FP((20.66±0.91)kg N/hm2)>OPT((12.79±1.33)kg N/hm2)>OPT+DCD((8.03±0.37)kg N/hm2)。与FP处理相比,OPT处理和OPT+DCD处理N2O年排放总量分别减少了38.09%和61.13%。各处理N2O排放系数介于0.36%—0.77%,低于IPCC 1.0%的推荐值。在目前的管理措施下,合理减少施氮量和添加硝化抑制剂是减少设施蔬菜地N2O排放量的有效途径。

施肥对稻田N2O排放的影响

肥料施用是影响稻田N2O排放的重要因素之一。以国内外相关文献为基础,综述了肥料的种类、施用量、施用方式和施用时间对稻田N2O排放的影响,指出了有待研究的加强对土壤N2O排放机理的研究;进一步研究肥料施用对稻田N2O排放的影响;进一步研究施肥管理措施对稻田温室气体(CH4和N2O)排放的交互影响,寻求科学合理、切实可行的减排措施。

施肥与灌溉对春玉米土壤N2O排放通量的影响

2007年在山西省榆次县利用静态箱自动监测系统对传统和优化两种施肥方式下春玉米土壤追肥和灌溉前后N2O排放通量进行了连续测定,该地区土壤质地为壤土,气候为温带大陆性半干旱气候。结果表明,灌溉和施肥对N2O的排放影响较大,当土壤含水量较低时,施肥并不会导致N2O通量迅速升高。在不灌溉的条件下施肥前后N2O的日排放通量特征为单峰型,凌晨4:00左右为最低值,下午16:00左右达到最高值,与空气和5cm土壤温度相关性均达到了极显著水平。施肥并灌溉后N2O排放通量迅速升高,一天之内能够迅速升高约50倍。灌溉后N2O日排放通量呈"N"字型走势,在达到最大值后变为单峰型,一周后日排放出现了直线下降和水平波动两种不同的走势。经检验施肥并灌溉后一周内优化施肥方式下N2O排放通量极显著低于传统施肥方式(P<0.01),优化施肥可以作为减排农田N2O排放的措施之一。